145 lines
5.3 KiB
Python
145 lines
5.3 KiB
Python
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# Copyright 2013 The Chromium Authors. All rights reserved.
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# Use of this source code is governed by a BSD-style license that can be
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# found in the LICENSE file.
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import os
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import sys
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_BASE_PATH = os.path.dirname(os.path.dirname(os.path.abspath(__file__)))
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_BINTREES_PATH = os.path.join(
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_BASE_PATH, os.pardir, os.pardir, 'third_party', 'bintrees')
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sys.path.insert(0, _BINTREES_PATH)
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from bintrees import FastRBTree # pylint: disable=F0401
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class ExclusiveRangeDict(object):
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"""A class like dict whose key is a range [begin, end) of integers.
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It has an attribute for each range of integers, for example:
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[10, 20) => Attribute(0),
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[20, 40) => Attribute(1),
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[40, 50) => Attribute(2),
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...
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An instance of this class is accessed only via iter_range(begin, end).
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The instance is accessed as follows:
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1) If the given range [begin, end) is not covered by the instance,
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the range is newly created and iterated.
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2) If the given range [begin, end) exactly covers ranges in the instance,
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the ranges are iterated.
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(See test_set() in tests/range_dict_tests.py.)
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3) If the given range [begin, end) starts at and/or ends at a mid-point of
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an existing range, the existing range is split by the given range, and
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ranges in the given range are iterated. For example, consider a case that
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[25, 45) is given to an instance of [20, 30), [30, 40), [40, 50). In this
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case, [20, 30) is split into [20, 25) and [25, 30), and [40, 50) into
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[40, 45) and [45, 50). Then, [25, 30), [30, 40), [40, 45) are iterated.
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(See test_split() in tests/range_dict_tests.py.)
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4) If the given range [begin, end) includes non-existing ranges in an
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instance, the gaps are filled with new ranges, and all ranges are iterated.
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For example, consider a case that [25, 50) is given to an instance of
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[30, 35) and [40, 45). In this case, [25, 30), [35, 40) and [45, 50) are
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created in the instance, and then [25, 30), [30, 35), [35, 40), [40, 45)
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and [45, 50) are iterated.
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(See test_fill() in tests/range_dict_tests.py.)
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"""
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class RangeAttribute(object):
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def __init__(self):
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pass
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def __str__(self):
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return '<RangeAttribute>'
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def __repr__(self):
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return '<RangeAttribute>'
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def copy(self): # pylint: disable=R0201
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return ExclusiveRangeDict.RangeAttribute()
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def __init__(self, attr=RangeAttribute):
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self._tree = FastRBTree()
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self._attr = attr
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def iter_range(self, begin=None, end=None):
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if not begin:
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begin = self._tree.min_key()
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if not end:
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end = self._tree.max_item()[1][0]
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# Assume that self._tree has at least one element.
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if self._tree.is_empty():
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self._tree[begin] = (end, self._attr())
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# Create a beginning range (border)
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try:
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bound_begin, bound_value = self._tree.floor_item(begin)
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bound_end = bound_value[0]
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if begin >= bound_end:
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# Create a blank range.
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try:
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new_end, _ = self._tree.succ_item(bound_begin)
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except KeyError:
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new_end = end
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self._tree[begin] = (min(end, new_end), self._attr())
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elif bound_begin < begin and begin < bound_end:
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# Split the existing range.
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new_end = bound_value[0]
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new_value = bound_value[1]
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self._tree[bound_begin] = (begin, new_value.copy())
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self._tree[begin] = (new_end, new_value.copy())
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else: # bound_begin == begin
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# Do nothing (just saying it clearly since this part is confusing)
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pass
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except KeyError: # begin is less than the smallest element.
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# Create a blank range.
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# Note that we can assume self._tree has at least one element.
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self._tree[begin] = (min(end, self._tree.min_key()), self._attr())
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# Create an ending range (border)
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try:
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bound_begin, bound_value = self._tree.floor_item(end)
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bound_end = bound_value[0]
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if end > bound_end:
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# Create a blank range.
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new_begin = bound_end
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self._tree[new_begin] = (end, self._attr())
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elif bound_begin < end and end < bound_end:
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# Split the existing range.
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new_end = bound_value[0]
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new_value = bound_value[1]
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self._tree[bound_begin] = (end, new_value.copy())
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self._tree[end] = (new_end, new_value.copy())
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else: # bound_begin == begin
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# Do nothing (just saying it clearly since this part is confusing)
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pass
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except KeyError: # end is less than the smallest element.
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# It must not happen. A blank range [begin,end) has already been created
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# even if [begin,end) is less than the smallest range.
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# Do nothing (just saying it clearly since this part is confusing)
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raise
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missing_ranges = []
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prev_end = None
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for range_begin, range_value in self._tree.itemslice(begin, end):
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range_end = range_value[0]
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# Note that we can assume that we have a range beginning with |begin|
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# and a range ending with |end| (they may be the same range).
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if prev_end and prev_end != range_begin:
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missing_ranges.append((prev_end, range_begin))
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prev_end = range_end
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for missing_begin, missing_end in missing_ranges:
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self._tree[missing_begin] = (missing_end, self._attr())
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for range_begin, range_value in self._tree.itemslice(begin, end):
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yield range_begin, range_value[0], range_value[1]
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def __str__(self):
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return str(self._tree)
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